/********************************************************************** * * PostGIS - Spatial Types for PostgreSQL * http://postgis.net * * PostGIS is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 2 of the License, or * (at your option) any later version. * * PostGIS is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with PostGIS. If not, see . * ********************************************************************** * * Copyright 2009 Paul Ramsey * **********************************************************************/ #include "liblwgeom_internal.h" #include "lwgeodetic.h" #include "lwgeom_log.h" #include #include GBOX* gbox_new(lwflags_t flags) { GBOX *g = (GBOX*)lwalloc(sizeof(GBOX)); gbox_init(g); g->flags = flags; return g; } void gbox_init(GBOX *gbox) { memset(gbox, 0, sizeof(GBOX)); } GBOX* gbox_clone(const GBOX *gbox) { GBOX *g = lwalloc(sizeof(GBOX)); memcpy(g, gbox, sizeof(GBOX)); return g; } /* TODO to be removed */ BOX3D* box3d_from_gbox(const GBOX *gbox) { BOX3D *b; assert(gbox); b = lwalloc(sizeof(BOX3D)); b->xmin = gbox->xmin; b->xmax = gbox->xmax; b->ymin = gbox->ymin; b->ymax = gbox->ymax; if ( FLAGS_GET_Z(gbox->flags) ) { b->zmin = gbox->zmin; b->zmax = gbox->zmax; } else { b->zmin = b->zmax = 0.0; } b->srid = SRID_UNKNOWN; return b; } /* TODO to be removed */ GBOX* box3d_to_gbox(const BOX3D *b3d) { GBOX *b; assert(b3d); b = lwalloc(sizeof(GBOX)); b->xmin = b3d->xmin; b->xmax = b3d->xmax; b->ymin = b3d->ymin; b->ymax = b3d->ymax; b->zmin = b3d->zmin; b->zmax = b3d->zmax; return b; } void gbox_expand(GBOX *g, double d) { g->xmin -= d; g->xmax += d; g->ymin -= d; g->ymax += d; if (FLAGS_GET_Z(g->flags) || FLAGS_GET_GEODETIC(g->flags)) { g->zmin -= d; g->zmax += d; } if (FLAGS_GET_M(g->flags)) { g->mmin -= d; g->mmax += d; } } void gbox_expand_xyzm(GBOX *g, double dx, double dy, double dz, double dm) { g->xmin -= dx; g->xmax += dx; g->ymin -= dy; g->ymax += dy; if (FLAGS_GET_Z(g->flags)) { g->zmin -= dz; g->zmax += dz; } if (FLAGS_GET_M(g->flags)) { g->mmin -= dm; g->mmax += dm; } } int gbox_union(const GBOX *g1, const GBOX *g2, GBOX *gout) { if ( ( ! g1 ) && ( ! g2 ) ) return LW_FALSE; else if (!g1) { memcpy(gout, g2, sizeof(GBOX)); return LW_TRUE; } else if (!g2) { memcpy(gout, g1, sizeof(GBOX)); return LW_TRUE; } gout->flags = g1->flags; gout->xmin = FP_MIN(g1->xmin, g2->xmin); gout->xmax = FP_MAX(g1->xmax, g2->xmax); gout->ymin = FP_MIN(g1->ymin, g2->ymin); gout->ymax = FP_MAX(g1->ymax, g2->ymax); gout->zmin = FP_MIN(g1->zmin, g2->zmin); gout->zmax = FP_MAX(g1->zmax, g2->zmax); return LW_TRUE; } int gbox_same(const GBOX *g1, const GBOX *g2) { if (FLAGS_GET_ZM(g1->flags) != FLAGS_GET_ZM(g2->flags)) return LW_FALSE; if (!gbox_same_2d(g1, g2)) return LW_FALSE; if (FLAGS_GET_Z(g1->flags) && (g1->zmin != g2->zmin || g1->zmax != g2->zmax)) return LW_FALSE; if (FLAGS_GET_M(g1->flags) && (g1->mmin != g2->mmin || g1->mmax != g2->mmax)) return LW_FALSE; return LW_TRUE; } int gbox_same_2d(const GBOX *g1, const GBOX *g2) { if (g1->xmin == g2->xmin && g1->ymin == g2->ymin && g1->xmax == g2->xmax && g1->ymax == g2->ymax) return LW_TRUE; return LW_FALSE; } int gbox_same_2d_float(const GBOX *g1, const GBOX *g2) { if ((g1->xmax == g2->xmax || next_float_up(g1->xmax) == next_float_up(g2->xmax)) && (g1->ymax == g2->ymax || next_float_up(g1->ymax) == next_float_up(g2->ymax)) && (g1->xmin == g2->xmin || next_float_down(g1->xmin) == next_float_down(g1->xmin)) && (g1->ymin == g2->ymin || next_float_down(g2->ymin) == next_float_down(g2->ymin))) return LW_TRUE; return LW_FALSE; } int gbox_is_valid(const GBOX *gbox) { /* X */ if ( ! isfinite(gbox->xmin) || isnan(gbox->xmin) || ! isfinite(gbox->xmax) || isnan(gbox->xmax) ) return LW_FALSE; /* Y */ if ( ! isfinite(gbox->ymin) || isnan(gbox->ymin) || ! isfinite(gbox->ymax) || isnan(gbox->ymax) ) return LW_FALSE; /* Z */ if ( FLAGS_GET_GEODETIC(gbox->flags) || FLAGS_GET_Z(gbox->flags) ) { if ( ! isfinite(gbox->zmin) || isnan(gbox->zmin) || ! isfinite(gbox->zmax) || isnan(gbox->zmax) ) return LW_FALSE; } /* M */ if ( FLAGS_GET_M(gbox->flags) ) { if ( ! isfinite(gbox->mmin) || isnan(gbox->mmin) || ! isfinite(gbox->mmax) || isnan(gbox->mmax) ) return LW_FALSE; } return LW_TRUE; } int gbox_merge_point3d(const POINT3D *p, GBOX *gbox) { if ( gbox->xmin > p->x ) gbox->xmin = p->x; if ( gbox->ymin > p->y ) gbox->ymin = p->y; if ( gbox->zmin > p->z ) gbox->zmin = p->z; if ( gbox->xmax < p->x ) gbox->xmax = p->x; if ( gbox->ymax < p->y ) gbox->ymax = p->y; if ( gbox->zmax < p->z ) gbox->zmax = p->z; return LW_SUCCESS; } int gbox_init_point3d(const POINT3D *p, GBOX *gbox) { gbox->xmin = gbox->xmax = p->x; gbox->ymin = gbox->ymax = p->y; gbox->zmin = gbox->zmax = p->z; return LW_SUCCESS; } int gbox_contains_point3d(const GBOX *gbox, const POINT3D *pt) { if ( gbox->xmin > pt->x || gbox->ymin > pt->y || gbox->zmin > pt->z || gbox->xmax < pt->x || gbox->ymax < pt->y || gbox->zmax < pt->z ) { return LW_FALSE; } return LW_TRUE; } int gbox_merge(const GBOX *new_box, GBOX *merge_box) { assert(merge_box); if ( FLAGS_GET_ZM(merge_box->flags) != FLAGS_GET_ZM(new_box->flags) ) return LW_FAILURE; if ( new_box->xmin < merge_box->xmin) merge_box->xmin = new_box->xmin; if ( new_box->ymin < merge_box->ymin) merge_box->ymin = new_box->ymin; if ( new_box->xmax > merge_box->xmax) merge_box->xmax = new_box->xmax; if ( new_box->ymax > merge_box->ymax) merge_box->ymax = new_box->ymax; if ( FLAGS_GET_Z(merge_box->flags) || FLAGS_GET_GEODETIC(merge_box->flags) ) { if ( new_box->zmin < merge_box->zmin) merge_box->zmin = new_box->zmin; if ( new_box->zmax > merge_box->zmax) merge_box->zmax = new_box->zmax; } if ( FLAGS_GET_M(merge_box->flags) ) { if ( new_box->mmin < merge_box->mmin) merge_box->mmin = new_box->mmin; if ( new_box->mmax > merge_box->mmax) merge_box->mmax = new_box->mmax; } return LW_SUCCESS; } int gbox_overlaps(const GBOX *g1, const GBOX *g2) { /* Make sure our boxes are consistent */ if ( FLAGS_GET_GEODETIC(g1->flags) != FLAGS_GET_GEODETIC(g2->flags) ) lwerror("gbox_overlaps: cannot compare geodetic and non-geodetic boxes"); /* Check X/Y first */ if ( g1->xmax < g2->xmin || g1->ymax < g2->ymin || g1->xmin > g2->xmax || g1->ymin > g2->ymax ) return LW_FALSE; /* Deal with the geodetic case special: we only compare the geodetic boxes (x/y/z) */ /* Never the M dimension */ if ( FLAGS_GET_GEODETIC(g1->flags) && FLAGS_GET_GEODETIC(g2->flags) ) { if ( g1->zmax < g2->zmin || g1->zmin > g2->zmax ) return LW_FALSE; else return LW_TRUE; } /* If both geodetic or both have Z, check Z */ if ( FLAGS_GET_Z(g1->flags) && FLAGS_GET_Z(g2->flags) ) { if ( g1->zmax < g2->zmin || g1->zmin > g2->zmax ) return LW_FALSE; } /* If both have M, check M */ if ( FLAGS_GET_M(g1->flags) && FLAGS_GET_M(g2->flags) ) { if ( g1->mmax < g2->mmin || g1->mmin > g2->mmax ) return LW_FALSE; } return LW_TRUE; } int gbox_overlaps_2d(const GBOX *g1, const GBOX *g2) { /* Make sure our boxes are consistent */ if ( FLAGS_GET_GEODETIC(g1->flags) != FLAGS_GET_GEODETIC(g2->flags) ) lwerror("gbox_overlaps: cannot compare geodetic and non-geodetic boxes"); /* Check X/Y first */ if ( g1->xmax < g2->xmin || g1->ymax < g2->ymin || g1->xmin > g2->xmax || g1->ymin > g2->ymax ) return LW_FALSE; return LW_TRUE; } int gbox_contains_2d(const GBOX *g1, const GBOX *g2) { if ( ( g2->xmin < g1->xmin ) || ( g2->xmax > g1->xmax ) || ( g2->ymin < g1->ymin ) || ( g2->ymax > g1->ymax ) ) { return LW_FALSE; } return LW_TRUE; } int gbox_contains_point2d(const GBOX *g, const POINT2D *p) { if ( ( g->xmin <= p->x ) && ( g->xmax >= p->x ) && ( g->ymin <= p->y ) && ( g->ymax >= p->y ) ) { return LW_TRUE; } return LW_FALSE; } /** * Warning, this function is only good for x/y/z boxes, used * in unit testing of geodetic box generation. */ GBOX* gbox_from_string(const char *str) { const char *ptr = str; char *nextptr; char *gbox_start = strstr(str, "GBOX(("); GBOX *gbox = gbox_new(lwflags(0,0,1)); if ( ! gbox_start ) return NULL; /* No header found */ ptr += 6; gbox->xmin = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ ptr = nextptr + 1; gbox->ymin = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ ptr = nextptr + 1; gbox->zmin = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ ptr = nextptr + 3; gbox->xmax = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ ptr = nextptr + 1; gbox->ymax = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ ptr = nextptr + 1; gbox->zmax = strtod(ptr, &nextptr); if ( ptr == nextptr ) return NULL; /* No double found */ return gbox; } char* gbox_to_string(const GBOX *gbox) { const size_t sz = 138; char *str = NULL; if ( ! gbox ) return lwstrdup("NULL POINTER"); str = (char*)lwalloc(sz); if ( FLAGS_GET_GEODETIC(gbox->flags) ) { snprintf(str, sz, "GBOX((%.8g,%.8g,%.8g),(%.8g,%.8g,%.8g))", gbox->xmin, gbox->ymin, gbox->zmin, gbox->xmax, gbox->ymax, gbox->zmax); return str; } if ( FLAGS_GET_Z(gbox->flags) && FLAGS_GET_M(gbox->flags) ) { snprintf(str, sz, "GBOX((%.8g,%.8g,%.8g,%.8g),(%.8g,%.8g,%.8g,%.8g))", gbox->xmin, gbox->ymin, gbox->zmin, gbox->mmin, gbox->xmax, gbox->ymax, gbox->zmax, gbox->mmax); return str; } if ( FLAGS_GET_Z(gbox->flags) ) { snprintf(str, sz, "GBOX((%.8g,%.8g,%.8g),(%.8g,%.8g,%.8g))", gbox->xmin, gbox->ymin, gbox->zmin, gbox->xmax, gbox->ymax, gbox->zmax); return str; } if ( FLAGS_GET_M(gbox->flags) ) { snprintf(str, sz, "GBOX((%.8g,%.8g,%.8g),(%.8g,%.8g,%.8g))", gbox->xmin, gbox->ymin, gbox->mmin, gbox->xmax, gbox->ymax, gbox->mmax); return str; } snprintf(str, sz, "GBOX((%.8g,%.8g),(%.8g,%.8g))", gbox->xmin, gbox->ymin, gbox->xmax, gbox->ymax); return str; } GBOX* gbox_copy(const GBOX *box) { GBOX *copy = (GBOX*)lwalloc(sizeof(GBOX)); memcpy(copy, box, sizeof(GBOX)); return copy; } void gbox_duplicate(const GBOX *original, GBOX *duplicate) { assert(duplicate); assert(original); memcpy(duplicate, original, sizeof(GBOX)); } size_t gbox_serialized_size(lwflags_t flags) { if (FLAGS_GET_GEODETIC(flags)) return 6 * sizeof(float); else return 2 * FLAGS_NDIMS(flags) * sizeof(float); } /* ******************************************************************************** ** Compute cartesian bounding GBOX boxes from LWGEOM. */ int lw_arc_calculate_gbox_cartesian_2d(const POINT2D *A1, const POINT2D *A2, const POINT2D *A3, GBOX *gbox) { POINT2D xmin, ymin, xmax, ymax; POINT2D C; int A2_side; double radius_A; LWDEBUG(2, "lw_arc_calculate_gbox_cartesian_2d called."); radius_A = lw_arc_center(A1, A2, A3, &C); /* Negative radius signals straight line, p1/p2/p3 are collinear */ if (radius_A < 0.0) { gbox->xmin = FP_MIN(A1->x, A3->x); gbox->ymin = FP_MIN(A1->y, A3->y); gbox->xmax = FP_MAX(A1->x, A3->x); gbox->ymax = FP_MAX(A1->y, A3->y); return LW_SUCCESS; } /* Matched start/end points imply circle */ if ( A1->x == A3->x && A1->y == A3->y ) { gbox->xmin = C.x - radius_A; gbox->ymin = C.y - radius_A; gbox->xmax = C.x + radius_A; gbox->ymax = C.y + radius_A; return LW_SUCCESS; } /* First approximation, bounds of start/end points */ gbox->xmin = FP_MIN(A1->x, A3->x); gbox->ymin = FP_MIN(A1->y, A3->y); gbox->xmax = FP_MAX(A1->x, A3->x); gbox->ymax = FP_MAX(A1->y, A3->y); /* Create points for the possible extrema */ xmin.x = C.x - radius_A; xmin.y = C.y; ymin.x = C.x; ymin.y = C.y - radius_A; xmax.x = C.x + radius_A; xmax.y = C.y; ymax.x = C.x; ymax.y = C.y + radius_A; /* Divide the circle into two parts, one on each side of a line joining p1 and p3. The circle extrema on the same side of that line as p2 is on, are also the extrema of the bbox. */ A2_side = lw_segment_side(A1, A3, A2); if ( A2_side == lw_segment_side(A1, A3, &xmin) ) gbox->xmin = xmin.x; if ( A2_side == lw_segment_side(A1, A3, &ymin) ) gbox->ymin = ymin.y; if ( A2_side == lw_segment_side(A1, A3, &xmax) ) gbox->xmax = xmax.x; if ( A2_side == lw_segment_side(A1, A3, &ymax) ) gbox->ymax = ymax.y; return LW_SUCCESS; } static int lw_arc_calculate_gbox_cartesian(const POINT4D *p1, const POINT4D *p2, const POINT4D *p3, GBOX *gbox) { int rv; LWDEBUG(2, "lw_arc_calculate_gbox_cartesian called."); rv = lw_arc_calculate_gbox_cartesian_2d((POINT2D*)p1, (POINT2D*)p2, (POINT2D*)p3, gbox); gbox->zmin = FP_MIN(p1->z, p3->z); gbox->mmin = FP_MIN(p1->m, p3->m); gbox->zmax = FP_MAX(p1->z, p3->z); gbox->mmax = FP_MAX(p1->m, p3->m); return rv; } static void ptarray_calculate_gbox_cartesian_2d(const POINTARRAY *pa, GBOX *gbox) { const POINT2D *p = getPoint2d_cp(pa, 0); gbox->xmax = gbox->xmin = p->x; gbox->ymax = gbox->ymin = p->y; for (uint32_t i = 1; i < pa->npoints; i++) { p = getPoint2d_cp(pa, i); gbox->xmin = FP_MIN(gbox->xmin, p->x); gbox->xmax = FP_MAX(gbox->xmax, p->x); gbox->ymin = FP_MIN(gbox->ymin, p->y); gbox->ymax = FP_MAX(gbox->ymax, p->y); } } /* Works with X/Y/Z. Needs to be adjusted after if X/Y/M was required */ static void ptarray_calculate_gbox_cartesian_3d(const POINTARRAY *pa, GBOX *gbox) { const POINT3D *p = getPoint3d_cp(pa, 0); gbox->xmax = gbox->xmin = p->x; gbox->ymax = gbox->ymin = p->y; gbox->zmax = gbox->zmin = p->z; for (uint32_t i = 1; i < pa->npoints; i++) { p = getPoint3d_cp(pa, i); gbox->xmin = FP_MIN(gbox->xmin, p->x); gbox->xmax = FP_MAX(gbox->xmax, p->x); gbox->ymin = FP_MIN(gbox->ymin, p->y); gbox->ymax = FP_MAX(gbox->ymax, p->y); gbox->zmin = FP_MIN(gbox->zmin, p->z); gbox->zmax = FP_MAX(gbox->zmax, p->z); } } static void ptarray_calculate_gbox_cartesian_4d(const POINTARRAY *pa, GBOX *gbox) { const POINT4D *p = getPoint4d_cp(pa, 0); gbox->xmax = gbox->xmin = p->x; gbox->ymax = gbox->ymin = p->y; gbox->zmax = gbox->zmin = p->z; gbox->mmax = gbox->mmin = p->m; for (uint32_t i = 1; i < pa->npoints; i++) { p = getPoint4d_cp(pa, i); gbox->xmin = FP_MIN(gbox->xmin, p->x); gbox->xmax = FP_MAX(gbox->xmax, p->x); gbox->ymin = FP_MIN(gbox->ymin, p->y); gbox->ymax = FP_MAX(gbox->ymax, p->y); gbox->zmin = FP_MIN(gbox->zmin, p->z); gbox->zmax = FP_MAX(gbox->zmax, p->z); gbox->mmin = FP_MIN(gbox->mmin, p->m); gbox->mmax = FP_MAX(gbox->mmax, p->m); } } int ptarray_calculate_gbox_cartesian(const POINTARRAY *pa, GBOX *gbox) { if (!pa || pa->npoints == 0) return LW_FAILURE; if (!gbox) return LW_FAILURE; int has_z = FLAGS_GET_Z(pa->flags); int has_m = FLAGS_GET_M(pa->flags); gbox->flags = lwflags(has_z, has_m, 0); LWDEBUGF(4, "ptarray_calculate_gbox Z: %d M: %d", has_z, has_m); int coordinates = 2 + has_z + has_m; switch (coordinates) { case 2: { ptarray_calculate_gbox_cartesian_2d(pa, gbox); break; } case 3: { if (has_z) { ptarray_calculate_gbox_cartesian_3d(pa, gbox); } else { double zmin = gbox->zmin; double zmax = gbox->zmax; ptarray_calculate_gbox_cartesian_3d(pa, gbox); gbox->mmin = gbox->zmin; gbox->mmax = gbox->zmax; gbox->zmin = zmin; gbox->zmax = zmax; } break; } default: { ptarray_calculate_gbox_cartesian_4d(pa, gbox); break; } } return LW_SUCCESS; } static int lwcircstring_calculate_gbox_cartesian(LWCIRCSTRING *curve, GBOX *gbox) { GBOX tmp = {0}; POINT4D p1, p2, p3; uint32_t i; if (!curve) return LW_FAILURE; if (curve->points->npoints < 3) return LW_FAILURE; tmp.flags = lwflags(FLAGS_GET_Z(curve->flags), FLAGS_GET_M(curve->flags), 0); /* Initialize */ gbox->xmin = gbox->ymin = gbox->zmin = gbox->mmin = FLT_MAX; gbox->xmax = gbox->ymax = gbox->zmax = gbox->mmax = -1*FLT_MAX; for ( i = 2; i < curve->points->npoints; i += 2 ) { getPoint4d_p(curve->points, i-2, &p1); getPoint4d_p(curve->points, i-1, &p2); getPoint4d_p(curve->points, i, &p3); if (lw_arc_calculate_gbox_cartesian(&p1, &p2, &p3, &tmp) == LW_FAILURE) continue; gbox_merge(&tmp, gbox); } return LW_SUCCESS; } static int lwpoint_calculate_gbox_cartesian(LWPOINT *point, GBOX *gbox) { if ( ! point ) return LW_FAILURE; return ptarray_calculate_gbox_cartesian( point->point, gbox ); } static int lwline_calculate_gbox_cartesian(LWLINE *line, GBOX *gbox) { if ( ! line ) return LW_FAILURE; return ptarray_calculate_gbox_cartesian( line->points, gbox ); } static int lwtriangle_calculate_gbox_cartesian(LWTRIANGLE *triangle, GBOX *gbox) { if ( ! triangle ) return LW_FAILURE; return ptarray_calculate_gbox_cartesian( triangle->points, gbox ); } static int lwpoly_calculate_gbox_cartesian(LWPOLY *poly, GBOX *gbox) { if ( ! poly ) return LW_FAILURE; if ( poly->nrings == 0 ) return LW_FAILURE; /* Just need to check outer ring */ return ptarray_calculate_gbox_cartesian( poly->rings[0], gbox ); } static int lwcollection_calculate_gbox_cartesian(LWCOLLECTION *coll, GBOX *gbox) { GBOX subbox = {0}; uint32_t i; int result = LW_FAILURE; int first = LW_TRUE; assert(coll); if ( (coll->ngeoms == 0) || !gbox) return LW_FAILURE; subbox.flags = coll->flags; for ( i = 0; i < coll->ngeoms; i++ ) { if ( lwgeom_calculate_gbox_cartesian((LWGEOM*)(coll->geoms[i]), &subbox) == LW_SUCCESS ) { /* Keep a copy of the sub-bounding box for later if ( coll->geoms[i]->bbox ) lwfree(coll->geoms[i]->bbox); coll->geoms[i]->bbox = gbox_copy(&subbox); */ if ( first ) { gbox_duplicate(&subbox, gbox); first = LW_FALSE; } else { gbox_merge(&subbox, gbox); } result = LW_SUCCESS; } } return result; } int lwgeom_calculate_gbox_cartesian(const LWGEOM *lwgeom, GBOX *gbox) { if ( ! lwgeom ) return LW_FAILURE; LWDEBUGF(4, "lwgeom_calculate_gbox got type (%d) - %s", lwgeom->type, lwtype_name(lwgeom->type)); switch (lwgeom->type) { case POINTTYPE: return lwpoint_calculate_gbox_cartesian((LWPOINT *)lwgeom, gbox); case LINETYPE: return lwline_calculate_gbox_cartesian((LWLINE *)lwgeom, gbox); case CIRCSTRINGTYPE: return lwcircstring_calculate_gbox_cartesian((LWCIRCSTRING *)lwgeom, gbox); case POLYGONTYPE: return lwpoly_calculate_gbox_cartesian((LWPOLY *)lwgeom, gbox); case TRIANGLETYPE: return lwtriangle_calculate_gbox_cartesian((LWTRIANGLE *)lwgeom, gbox); case COMPOUNDTYPE: case CURVEPOLYTYPE: case MULTIPOINTTYPE: case MULTILINETYPE: case MULTICURVETYPE: case MULTIPOLYGONTYPE: case MULTISURFACETYPE: case POLYHEDRALSURFACETYPE: case TINTYPE: case COLLECTIONTYPE: return lwcollection_calculate_gbox_cartesian((LWCOLLECTION *)lwgeom, gbox); } /* Never get here, please. */ lwerror("unsupported type (%d) - %s", lwgeom->type, lwtype_name(lwgeom->type)); return LW_FAILURE; } void gbox_float_round(GBOX *gbox) { gbox->xmin = next_float_down(gbox->xmin); gbox->xmax = next_float_up(gbox->xmax); gbox->ymin = next_float_down(gbox->ymin); gbox->ymax = next_float_up(gbox->ymax); if ( FLAGS_GET_M(gbox->flags) ) { gbox->mmin = next_float_down(gbox->mmin); gbox->mmax = next_float_up(gbox->mmax); } if ( FLAGS_GET_Z(gbox->flags) ) { gbox->zmin = next_float_down(gbox->zmin); gbox->zmax = next_float_up(gbox->zmax); } } uint64_t gbox_get_sortable_hash(const GBOX *g, const int32_t srid) { union floatuint { uint32_t u; float f; }; union floatuint x, y; /* * Since in theory the bitwise representation of an IEEE * float is sortable (exponents come before mantissa, etc) * we just copy the bits directly into an int and then * interleave those ints. */ if (FLAGS_GET_GEODETIC(g->flags)) { GEOGRAPHIC_POINT gpt; POINT3D p; p.x = (g->xmax + g->xmin) / 2.0; p.y = (g->ymax + g->ymin) / 2.0; p.z = (g->zmax + g->zmin) / 2.0; normalize(&p); cart2geog(&p, &gpt); /* We know range for geography, so build the curve taking it into account */ x.f = 1.5 + gpt.lon / 512.0; y.f = 1.5 + gpt.lat / 256.0; } else { x.f = (g->xmax + g->xmin) / 2; y.f = (g->ymax + g->ymin) / 2; /* * Tweak for popular SRID values: push floating point values into 1..2 range, * a region where exponent is constant and thus Hilbert curve * doesn't have compression artifact when X or Y value is close to 0. * If someone has out of bounds value it will still expose the arifact but not crash. * TODO: reconsider when we will have machinery to properly get bounds by SRID. */ if (srid == 3857 || srid == 3395) { x.f = 1.5 + x.f / 67108864.0; y.f = 1.5 + y.f / 67108864.0; } else if (srid == 4326) { x.f = 1.5 + x.f / 512.0; y.f = 1.5 + y.f / 256.0; } } return uint32_hilbert(y.u, x.u); }